市场调查报告书
商品编码
1209792
到 2028 年的激光打标机市场预测——按激光类型、产品类型、材料、方法、应用、最终用户和地区进行的全球分析Laser Marking Machine Market Forecasts to 2028 - Global Analysis By Laser Type, Offering, Product Type, Material, Method, Application, End User and Geography |
根据 Stratistics MRC 的数据,2022 年全球激光打标机市场规模将达到 30.6 亿美元,预计到 2028 年将达到 53 亿美元,预测期内復合年增长率为 9.6%。在成长。
LASER是Light Amplification by Stimulated Emission of Radiation的缩写,意思是通过辐射刺激进行光放大。 激光标记是一种使用聚焦光束在各种材料表面创建永久标记的方法,例如序列号、部件标籤、条形码、单个部件号、有效期、品牌名称等。 激光打标的应用范围很广,通常使用光纤激光器、连续波激光器、脉衝激光器等激光加工机来进行。 激光打标机提供永久、更快和更准确的打标和雕刻。
根据印度汽车製造商协会 (SIAM) 最近发布的一份报告,印度 2021 年的汽车出口量将超过 561.7 万辆。 预计这一数字在未来几年将显着增加,并被认为为激光打标设备市场提供了持续的机会。
市场动态
驱动程序
激光打标机优于传统打标技术
与传统的材料标记程序相比,激光标记设备具有更高的准确性、可读性、更低的人工成本和更少的损失。 与点针打标等传统打标技术相比,激光打标技术速度非常快。 点针打标大约需要 5 秒,而激光可以在大约 1 秒内形成一个二维图案,因此标记和雕刻许多物体的工厂可以显着缩短时间。 此外,由于它比传统的雕刻更耐用,因此它被高度评价为一种高度通用的标记,可用于标记飞机的各种部件。 激光打标设备的典型用途包括退火、碳迁移、发泡和着色。
抑製剂
安装成本高
工艺、系统和应用中使用的激光器功率从数百瓦到数千瓦不等。 高功率激光器用于大型激光显示器、医疗和军事应用、研究、激光聚变以及焊接、切割和钻孔等材料加工应用。 在汽车和製造行业,激光打标有助于减少劳动力和相关成本,但其实施需要大量投资。 因此,与使用激光打标设备相关的高初始投资和运营成本可能会阻碍整个市场的增长。
机会
扩大激光打标技术的采用
激光打标技术因其成本效益、产品独特性和可靠性而被广泛应用于各个工业领域。 政府机构,尤其是医疗保健和国防部门,已经引入了对各种对象进行永久标记的标准,以用于识别、可追溯性和记录保存目的。 此外,该技术还广泛应用于汽车和航空航天工业。 在汽车领域,标记用于在不影响轮胎构造的情况下在轮胎上雕刻序列号。 由于其耐用性,激光打标机被认为是标记飞机各个部件的可行解决方案。 因此,上述因素为市场增长提供了有利可图的机会。
威胁
与高功率激光器相关的技术复杂性
高功率激光器的使用存在许多障碍。 主要问题是连续波操作需要一个或多个强大的泵浦源,例如二极管泵浦激光器,以获得高功率。 另一个技术问题是长时间 CW 操作需要高效壁式插头。 这是因为无法确保高输出时的效率。 此外,在高功率激光器中还观察到拉曼散射、布里渊散射、四波混频等非线性现象。
COVID-19 的影响
COVID-19 的爆发增加了医疗行业对激光打标机和服务的需求。 用于COVID治疗的口罩等医疗器械的需求量大幅增加,医疗产品和器械製造商推出了激光打标机,用于识别带有激光打标的品牌名称和证书。 对使用聚丙烯管进行样本采集的 COVID-19 检测试剂盒的需求也在不断增长。 这些套件的外部采用紫外激光标记多个参数,因此在任何阶段都不会影响患者身份识别。
预计在预测期内光纤激光器部分将成为最大的部分
由于光纤激光器灵活、光学质量高、功率高和机器紧凑等多项优势,预计光纤激光器部分在预测期内将呈现最快的复合年增长率。 使用光纤激光束在产品上留下印记的过程称为光纤激光打标。 它从光中获取聚焦能量,并将其用于标记设备以产生激光束。 用于坚硬和粗糙的表面。 光纤激光器提供比传统激光刻印机高得多的功率。 光纤激光器可以标记多种材料,但最适合标记金属。 其高输出使其成为退火和雕刻应用的理想选择。
预计机床领域在预测期内的复合年增长率最高。
预计机床领域在预测期内将呈现最快的复合年增长率。 机床製造是激光打标和雕刻系统的主要应用领域。 激光在机床上创建永久字母数字特征(如批号、一维和二维条码、设计、製造日期、品牌名称、製造商代码和徽标)的能力的增长将推动细分市场的增长。它是 在製造业中,运营现代化正在通过工厂自动化和智能工厂等概念取得进展,以通过批量生产提高生产能力。 此外,越来越多地使用机器人和传感器强调了对工具识别和识别的需求,推动了对激光打标机的需求。
市场份额最高的地区
由于製造工厂越来越多地采用激光打标机,预计亚太地区在预测期内将占据最大的市场份额。 中国机床行业采用先进的生产工艺以及航空航天和军工行业的发展正在推动市场扩张。 此外,越来越多的外国投资和许多公司的製造工厂转移到印度和中国等国家也有助于该地区的持续主导地位。
复合年增长率最高的地区
由于汽车和汽车零部件製造商在德国、欧洲、意大利和法国等国家/地区的主导地位,预计欧洲在预测期内的复合年增长率最高。 此外,航空航天和运输行业的显着增长预计将推动该地区的市场增长。 例如,2018 年 12 月,英国政府承诺向未来飞行挑战赛投入约 3.35 亿美元,用于资助航空技术的改进。
主要发展
2020 年 1 月,Trumpf 收购了法国激光技术初创公司 GLOphotonics 的少数股权。
2019 年 11 月,相干公司宣布推出一款可切换可调环模 (ARM) 光纤激光器,能够为两个独立的进程或工作站依次供电。
2019年8月,大族激光推出多轴超高速微加工装置,可以控制激光器的旋转,控制X、Y、Z三个方向的运动。
2019 年 5 月,TYKMA Electrox 宣布与 Cerakote 建立合作伙伴关係,Cerakote 是一家为多种应用提供薄膜陶瓷涂层的供应商。 该合作伙伴关係旨在通过将 Cerakote 涂层产品与前者在各种 3D 物体上的激光标记功能相结合来提供先进的成像。
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According to Stratistics MRC, the Global Laser Marking Machine Market is accounted for $3.06 billion in 2022 and is expected to reach $5.30 billion by 2028 growing at a CAGR of 9.6% during the forecast period. The term LASER stands for Light Amplification by Stimulated Emission of Radiation. Laser marking is a permanent method that uses a concentrated light beam to generate a permanent mark on the surface of a range of materials such as serial numbers, component labelling, barcodes, individual part numbers, best-before-date, brand name, and many others. Laser marking spans a wide range of applications and is often conducted with a fibre, continuous-wave laser machine, or pulsed laser machine. The Laser marking machines offer permanent, faster, and accurate marking and engraving.
According to a recently released report by the Society of Indian Automobile Manufacturers (SIAM), India exported more than 5,617,000 units of automobiles in 2021. This number is expected to increase substantially in the future, creating sustainable opportunities for the Laser marking equipment market.
Market Dynamics:
Driver:
Higher performance of laser markers over traditional marking techniques
Laser marking systems provide greater accuracy, readability, cheaper labor costs, and less loss than traditional material marking procedures. When compared to traditional marking techniques such as dot peen marking, laser marking technologies are exceptionally rapid. They make a 2D pattern in around a second or less, compared to 5 seconds for dot peen marking systems, saving a substantial amount of time in plants where many objects need to be marked or engraved. Furthermore, as compared to traditional engraving procedures, laser marking is regarded as a versatile choice for marking a wide variety of aircraft parts due to its excellent endurance. The most typical uses for laser marking systems include annealing, carbon migration, foaming, and coloring.
Restraint:
High deployment cost
Lasers used in processes, systems, and applications range in power from a few hundred to thousands of watts. High power lasers are employed in large-scale laser displays, medical and military applications, research, laser-induced nuclear fusion, and material processing applications such as welding, cutting, and drilling. Although laser marking aids in the reduction of labour and related expenses in the automotive and manufacturing industries, its implementation requires a significant investment. As a result, the high initial investments and operational costs associated with the use of laser marking machines may impede overall market growth.
Opportunity:
Growing adoption of laser marking technology
The laser marking technology is increasingly being adopted across various industrial verticals due to its cost-effectiveness, product uniqueness, and reliability. Administrations are implementing standards for permanent marking on a variety of objects for the purposes of evidence of identity, traceability, and recordkeeping, particularly in the healthcare and defence sectors. Furthermore, the technique is being widely adopted by the automotive and aerospace industries. Markers are used in the automotive sector to engrave serial numbers on tire without affecting the tires structure. Because of its excellent endurance, laser marking is regarded as a viable solution for marking a wide range of aircraft parts. Thus, the above factors provide lucrative opportunities for the market growth.
Threat:
Technical complexities related to high power lasers
The use of high-power lasers presents numerous obstacles. The main problem is the need for one or more powerful pump sources like diode-pumped lasers for high output power in continuous-wave operation. Another technological problem is the demand for a high-efficiency wall plug for long-term CW operations. This is owing to the inability to attain efficiency at high power levels. Nonlinear phenomena such as Raman scattering, Brillouin scattering, and four-wave mixing are also observed in high-power lasers.
COVID-19 Impact
The medical sector has seen an increase in demand for laser marking machines and services as a result of the COVID-19 outbreak. There has been a significant increase in demand for masks and other medical devices used for COVID therapy, as well as the adoption of laser marking machines by medical product and device makers to identify their brand name and certificates using laser marking. In addition, COVID-19 testing kits with polypropylene tubes for sample collection have been in high demand. These kits are labelled from the outside with a UV laser for several parameters to ensure that patient identification is not compromised at any stage.
The fiber laser segment is expected to be the largest during the forecast period
The fiber laser segment is anticipated to witness the fastest CAGR growth during the forecast period, due to its several advantages, including flexible fibre light, high optical quality, high output power, and machine compactness. The process of leaving an impression on goods with a fibre laser beam of light is referred to as fibre laser marking. The laser beam is created by extracting focused energy from light and using it in the marking machine. They are utilised on tough and rough surfaces. Fiber lasers provide a substantially higher output power than traditional laser markers. Fiber lasers can mark a wide range of materials, but they are best suited for metal marking. Because of their high power, they are ideal for annealing and engraving applications.
The machine tool segment is expected to have the highest CAGR during the forecast period
The machine tool segment is anticipated to witness the fastest CAGR growth during the forecast period. Machine tool manufacturing is the major application area of laser marking and engraving systems. The increasing capability of lasers to produce permanent alphanumeric features on machine tools, such as batch numbers, 1D & 2D bar codes, designs, manufacturing dates, brand names, manufacturer codes, and logos, is driving segment expansion. The manufacturing sector is modernising its operations with concepts such as factory automation and smart factories in order to increase production capacity through batch production. Furthermore, the growing usage of robotics and sensors has underlined the need of tool identification and recognition, driving demand for laser marking machines.
Region with highest share:
Asia Pacific is projected to hold the largest market share during the forecast period owing to the increased adoption of laser marking machines in manufacturing factories in the region. The adoption of advanced production processes in the Chinese machine tool sector, as well as the region's thriving aerospace and military industries, are driving market expansion. Furthermore, its sustained dominance can be attributable to growing foreign investment and the movement of numerous corporations' manufacturing plants to nations such as India and China.
Region with highest CAGR:
Europe is projected to have the highest CAGR over the forecast period, owing to the dominance of automotive and automotive component manufacturers in countries such as Germany, Europe, Italy, and France. Furthermore, significant growth in the aerospace and transportation industries is likely to boost market growth in the region. For example, the United Kingdom government decided in December 2018 to contribute roughly USD 335.0 million in the Future Flight Challenge to fund improvements in aeronautical technology.
Key players in the market
Some of the key players profiled in the Laser Marking Machine Market include Videojet Technologies Inc, TRUMPF Group, Coherent Inc., Han's Laser Group, Novanta Inc., Epilog Corporation, Mecco Partners LLC, IPG Photonics Corporation, Vytek Laser Systems, TYKMA Electrox Inc., ROFIN-SINAR Laser GmbH, Wisely Laser Machinery Limited, Universal Laser Systems Inc., Trotec Laser GmbH, LaserStar Technologies Corporation, Telesis Technologies, Inc.
Key Developments:
In January 2020, Trumpf acquired a minority stake in GLOphotonics, a France-based laser technology startup.
In November 2019, Coherent launched a switchable adjustable ring mode (ARM) fiber laser that has the ability to sequentially power two separate processes or workstations.
In August 2019, Han's Laser launched multi-axis ultrafast micromachining equipment that can control the rotation of the laser and can control X, Y, Z motion in three directions.
In May 2019, TYKMA Electrox announced a collaboration with Cerakote, a provider of thin-film ceramic coating for several applications. The partnership was aimed at providing advanced imaging on products with Cerakote coatings by blending it with the former's laser marking abilities on a variety of 3D objects.
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Note: Tables for North America, Europe, APAC, South America, and Middle East & Africa Regions are also represented in the same manner as above.